Brake with field responsive material

ABSTRACT

A controllable brake includes a housing and a rotor supported on a shaft. The rotor is housed within a chamber containing a field controllable material which is acted upon by a magnetic field generator to impede movement of the rotor. The shaft is supported by bearings. The controllable brake housing defines a second housing chamber adapted to enclose means for monitoring and/or controlling the brake and in this way, an integrated, compact controllable brake is provided.

CROSS REFERENCE

This application is a Continuation In Part (CIP) of pending U.S. patent application Ser. No. 11/042,277 filed Jan. 25, 2005, which is a Divisional of U.S. patent application Ser. No. 10/037,118 filed on Oct. 25, 2001, now U.S. Pat. No. 6,854,573, all of which this application claims the benefit of, and incorporates by reference.

FIELD OF THE INVENTION

The invention relates to the area of brakes, clutches, resistance generating devices and motion control devices. Specifically the invention relates to devices employing a field responsive material for controlling torque in rotary acting devices or linearly-acting devices.

BACKGROUND OF THE INVENTION

Devices employing a field responsive material for damping and controlling vibration and shock are known. Such a field responsive material may comprise a suitable magnetorheological (MR) material well known to one skilled in the art. As the description proceeds, the field responsive material may be referred to as either “MR medium” or “MR material” or “field responsive material” or “field controllable material”. Additionally, for purposes of clarity throughout this disclosure, devices employing such a field controllable material will generally be referred to as either “magnetorheological devices” or “MR devices” or “field controllable devices” or “field responsive devices”. MR devices may be of the “rotary-acting” or “linear-acting” variety, and can provide variable controlled torques or forces. Known MR devices may include for example rotary brakes, rotary clutches and linear dampers.

Field controllable devices typically include a housing or chamber that contains a quantity of a magnetically controllable material, and a moveable member, such as a piston or rotor mounted for movement through the material in the housing. A magnetic field generator (a coil or permanent magnet) produces a magnetic field through one or more pole pieces for directing a magnetic flux through desired regions of the controllable material.

The field controllable material employed in MR devices is comprised of soft-magnetic or magnetizable particles dispersed within a carrier, frequently a liquid. While many current applications employ a liquid carrier, it also will be appreciated that the carrier may also comprise gaseous dispersions, for example as a powder. However the required carrier is dependent on the specific application for the MR device. Typical particles include carbonyl iron or stainless steel, and the like, having various shapes, but which are preferably spherical and have mean diameters of between about 0.1 μm to about 500 μm. The carrier materials may include hydraulic oils for example.

In operation, the field controllable material exhibits a rheology change, i.e., an increase in viscosity or resistance to shear, upon being exposed to a magnetic field. The greater the magnitude of the magnetic field passing through the field controllable material, the higher the shear stress or torque that can be achieved by the MR device. Such MR materials are readily commercially available in various formulations from Lord Corporation of Cary, N.C., and the selection of the particular MR material is typically determined by the desired application for the MR device.

MR devices, in particular MR brakes, are used whenever it is necessary to control motion, and in applications where it is desirable to control the velocity or energy dissipation in a dynamic system. This includes systems irrespective of whether the systems are driven by pneumatics, manually by an operator or by another motive force generating means. The specific application is controllable energy dissipation, in the rotary sense. Energy is removed from a dynamic system to give position and/or velocity control, or to generate a desired resistance torque.

Examples of such systems include drive-by-wire systems such as might be applied in a vehicle, fork lift, or the like. In such applications, it is desirable to maintain the function of traditional mechanical controls in a system controlled in a different manner. For example, a steering wheel may be used which implements a magnetic brake, but through the use of electronics provides signals to a motor such as a servo motor, to actuate the device to be controlled, such as steered wheels, flight control surfaces, etc. Depending on the position of the device as moved by the servo motors, it may be desirable to provide tactile feedback to the operator. Thus, when turning a wheel which incorporates an MR brake, position sensors and appropriate electronics may be implemented to provide torque feedback by actuating the field generator in the magnetic brake to affect the MR material and increase resistance to motion by a rotor in the brake. For example, such an application can be a steering wheel, to which it is attached, as to maintain a realistic “feel” for the operator, in a manner duplicating the tactile feedback of purely mechanical systems.

Often, the space allotted for the use of these devices is limited and specific applications require that the devices be maintained as small as possible, while still providing sufficient resistance to the control device. It would be desirable to provide a compact, integrated device to accommodate space limitations in specific applications.

The foregoing illustrates design criteria known to exist in present field responsive devices. Thus it is apparent that it would be advantageous to provide an alternative directed to providing a field responsive device that addresses one or more of the criteria associated with present devices. Accordingly, a suitable alternative is provided including features more fully disclosed hereinafter. There is a need for controllable brakes for controlling motion. There is a need for controllable brakes and a method of accurately and economically controlling motion. There is a need for an economically feasible method of controlling motion accurately with a brake utilizing magnetic fields. There is a need for a robust controllable brake and method of making controllable brakes with improved performance. There is a need for an economic controllable brake and method of controlling motion with a magnetic field responsive material and a magnetic field generator.

SUMMARY OF THE INVENTION

In one aspect of the present invention, a controllable brake includes a rotor having first and second rotor surfaces, an outer periphery and at least one working portion proximate to or at the outer periphery. A shaft has the rotor connected at one end of the shaft in a manner to restrain relative rotation therebetween. A housing includes a first chamber housing the rotor therein in a manner to allow rotation thereof (rotatably housing), and including a magnetic field generator spaced from the rotor, and configured and positioned for conveying a magnetic flux extending through controllable material between the field generator and working portion, in a direction toward the at least one working portion of the rotor. The controllable material is contained within the first chamber in contact with the at least one working portion of the rotor. Electronics are provided for controlling and/or monitoring operation of the brake. Such electronics may include sensors, power amplifiers, signal conditioners, analog or digital circuitry employing control algorithms, communications circuitry, as well as other like circuitry and like components as will be readily apparent to those of ordinary skill in the art. More specifically, the shaft may be supported by at least two bearings spaced from each other. The bearings are mounted on the housing. The control electronics are housed in a second chamber. Typically, the second chamber is adjacent the first chamber.

For purposes of the description of the embodiments of the invention, the term “working portion” refers to the portion of the rotor which, upon the application of a magnetic field, is engaged by the MR medium to impede movement of the rotor.

In another aspect of the invention, a controllable MR brake includes a rotor comprising first and second rotor surfaces, an outer periphery, and a working portion on at least one of the first and second rotor surfaces at a position proximate to the outer periphery. The rotor is fixed to a shaft at one shaft end and the rotor and the shaft are rotatable together. A housing includes a first chamber rotatably housing the rotor therein, and including a magnetic field generator spaced from the rotor and configured and positioned for conveying a magnetic flux acting on a volume of controllable material located in the first housing chamber in contact with at least one surface proximate the outer periphery. The controllable material is contained within the first chamber to be in contact with at least the working portion of the rotor. Electronics serve to control and monitor operation of the brake. In a more specific aspect, a second chamber is included in the housing and houses the electronics therein to provide a compact and integrated MR brake with electronics housed therein.

The magnetic field generator may be an electromagnetic coil, with poles positioned for conveying a flux extending through the field controllable material at least on one side of the rotor, with the rotor configured as a disk. Alternatively, the magnetic field generator can be an electromagnetic coil with poles positioned on both sides of the rotor on the working surfaces thereof for conveying flux extending on both sides, with the rotor also being configured as a disk.

In specific applications, the shaft for the rotor is supported for rotation by two bearings in the housing, which allow for a second chamber to house electronics, and seals are provided around the shaft at the point of entry into the first chamber for sealing the first chamber to prevent the migration of the controllable material from the first chamber to the second chamber.

In another more specific aspect of the invention, a return-to-center device such as a torsional spring or like device may be provided to urge the rotor to return to a relative center position.

Yet still further, the connection between the shaft and the rotor may be arranged so as to allow some backlash between the rotor and the shaft, and the control electronics can be arranged for detecting movement of the shaft and for causing the magnetic field generator to reduce magnetic field in response to the shaft movement to allow easy movement of the control device connected to the brake, such as a steering wheel, back from an end-of-movement position.

In an alternative configuration, the rotor can be configured to have a working portion on the outer periphery and on the rotor surfaces at a portion proximate the outer periphery. The magnetic field generator which is spaced from the rotor can be configured for conveying a magnetic flux extending through controllable material in directions both, (1) parallel to the shaft and perpendicular to the working portion proximate the outer periphery and (2) perpendicular to the shaft and to the outer periphery of the rotor. This can be done by configuring, for example, the magnetic field generator as an electromagnetic coil with one pole adjacent the working portion on one surface of the rotor, and the other pole extending outside of the outer periphery, and at least co-extensive with the outer periphery of the rotor.

In yet still a further aspect, the rotor can be configured as having first and second rotor surfaces and an outer periphery. The outer periphery is shaped such that the working portion of the rotor faces radially outward from the rotor and the shaft and has sufficient working surface as to allow a magnetic field to induce sufficient shear stress within the controllable material acting on the working surface to inhibit or prevent motion of the rotor. Such a rotor configuration can include a drum-like configuration in which the outer periphery is shaped fairly wide relative to the actual thickness of the rest of the rotor. In this manner, the magnetic field generator is configured to generate a magnetic field which acts on the controllable material adjacent and in contact with the working portion.

In such a configuration, the walls of the chamber in which the rotor is housed can be tapered. The taper can be an amount sufficient to enhance migration of field controllable material away from the shaft and toward the working surface of the rotor. In addition, other alternative structures can be built into the rotor proximate the shaft, the housing, and/or on the shaft itself as to create a tortuous path for the field controllable material, making it difficult to have it migrate towards the shaft and in the direction of seals associated with the shaft to retain the material within the chamber housing the rotor. The seals used can be conventional seals and/or of other configurations as will be readily apparent to those of ordinary skill in the art, such as “v-seals” of conventional construction. Similarly, conventional bearings, such as roller elements or bearings, can be used in supporting the shafts as well as other types of bearings which are well known to those of ordinary skill in the art, interchangeable therewith, including, without limitation, dry shaft bearings and the like.

In an embodiment the invention includes a controllable brake. The controllable brake preferably includes a housing including a first chamber and a second chamber. The controllable brake preferably includes a shaft, the shaft extending through the first chamber and the second chamber with an axis of rotation, the shaft having a first shaft end. The controllable brake preferably includes a controllable brake rotor made integral with the shaft, the rotor housed in the first chamber. The controllable brake preferably includes a controllable brake magnetic field generator located in the first chamber proximate the controllable brake rotor, the controllable brake magnetic field generator for generating a controllable magnetic field strength. The controllable brake preferably includes a controllable brake rotating magnetic target integrated with the shaft proximate the first shaft end, the controllable brake rotating magnetic target housed in the second chamber. The controllable brake preferably includes a controllable brake electronics circuit board mounted in the second chamber, the controllable brake electronics circuit board having a control board plane, the control board plane oriented normal to the shaft axis of rotation. The controllable brake preferably includes a first electronic noncontacting magnetic sensor having a first sensor plane, the first electronic noncontacting magnetic sensor integrated on the controllable brake electronics circuit board with the first sensor plane parallel with the control board plane. The controllable brake preferably includes a second electronic noncontacting magnetic sensor having a second sensor plane, the second electronic noncontacting magnetic sensor integrated on the controllable brake electronics circuit board with the second sensor plane parallel with the control board plane with the control board plane between the first sensor plane and the second sensor plane, the first electronic noncontacting magnetic sensor and the second electronic noncontacting magnetic sensor monitoring the rotation of the controllable brake rotating magnetic target and outputting a rotational position of the controllable brake rotating magnetic target wherein the controllable magnetic field strength generated by the controllable brake magnetic field generator is determined by the rotational position to control a relative motion of the controllable brake rotor.

In an embodiment the invention includes a controllable brake. The controllable brake preferably includes a rotating magnetic target. The controllable brake preferably includes a magnetically permeable rotor. The controllable brake preferably includes a shaft connected to the magnetically permeable rotor. The controllable brake preferably includes a housing having a first housing chamber rotatably housing the magnetically permeable rotor therein, and including a magnetic field generator spaced from the magnetically permeable rotor, and configured and positioned for generating a controllable magnetic field to control a relative motion of the magnetically permeable rotor, and a second housing chamber containing control electronics therein, the second housing chamber electronics including at least a first oriented electronic noncontacting magnetic sensor, the at least first oriented electronic noncontacting magnetic sensor oriented relative to the rotating magnetic target and the shaft wherein the at least first oriented electronic noncontacting magnetic sensor monitors the rotation of the rotating magnetic target.

In an embodiment the invention includes a method of controlling motion. The method preferably includes providing a housing having a first housing chamber and a second housing chamber. The method preferably includes providing a shaft with a magnetically permeable rotor, the shaft including a rotating magnetic target distal from the magnetically permeable rotor. The method preferably includes providing a magnetic field generator for generating a magnetic field with a controllable field strength for controlling a relative motion of the magnetically permeable rotor. The method preferably includes providing at least a first electronic noncontacting magnetic sensor, the at least first electronic noncontacting magnetic sensor integrated on an operation electronic control board having a control board plane. The method preferably includes disposing the magnetically permeable rotor and the magnetic field generator in the first housing chamber. The method preferably includes disposing the rotating magnetic target and the at least a first electronic noncontacting magnetic sensor in the second housing chamber, wherein the operation electronic control board is in electrical communication with the magnetic field generator and the control board plane is oriented relative to the rotating magnetic target, wherein the at least first electronic noncontacting magnetic sensor provides a detected measured rotational position of the rotating magnetic target with the controllable field strength generated in relationship to the detected measured rotational position sensed by the at least first electronic noncontacting magnetic sensor.

In an embodiment the invention includes a method of making a motion control brake for controlling motion. The method preferably includes providing a magnetic field generator for generating a magnetic field with a controllable field strength for controlling a relative motion of a movable brake member. The method preferably includes providing a magnetic target which moves with the relative motion of the movable brake member. The method preferably includes providing an electronic circuit board having a circuit board plane, a first oriented electronic noncontacting magnetic sensor having a first oriented sensor plane, the first electronic noncontacting magnetic sensor integrated on the electronic circuit board with the first sensor plane parallel with the circuit board plane, a second oriented electronic noncontacting magnetic sensor having a second oriented sensor plane, the second electronic noncontacting magnetic sensor integrated on the electronic circuit board with the second sensor plane parallel with the circuit board plane with the circuit board plane between the second sensor plane and the first sensor plane. The method preferably includes disposing the electronic circuit board proximate the magnetic target wherein the first electronic noncontacting magnetic sensor and the second electronic noncontacting magnetic sensor provide a detected measured magnetic target position with the controllable field strength generated by the magnetic field generator determined by the detected measured magnetic target position.

In an embodiment the invention includes a method of making a control system. The method preferably includes providing a control system rotating magnetic target having an axis of rotation. The method preferably includes providing a control system electronic circuit board having a circuit board plane and a first circuit board side and an opposite second circuit board side, a first oriented electronic noncontacting magnetic sensor integrated on the electronic circuit board first circuit board side, a second oriented electronic noncontacting magnetic sensor integrated on the electronic circuit board second circuit board side. The method preferably includes disposing the control system electronic circuit board proximate the control system rotating magnetic target with a projected extension of the axis of rotation extending through the first oriented electronic noncontacting magnetic sensor and the second oriented electronic noncontacting magnetic sensor wherein the first electronic noncontacting magnetic sensor and the second electronic noncontacting magnetic sensor provide a plurality of detected measured magnetic target rotary position outputs.

In an embodiment the invention includes a method of controlling motion. The method preferably includes providing a magnetic field generator for generating a magnetic field with a controllable field strength. The method preferably includes providing a field responsive controllable material, the field responsive controllable material affected by the magnetic field generator magnetic field. The method preferably includes providing a magnetic target. The method preferably includes providing at least a first electronic noncontacting magnetic sensor, the at least first electronic noncontacting magnetic sensor integrated on an operation electronic control board having a control board plane, the operation electronic control board in electrical communication with the magnetic field generator and the control board plane oriented relative to the magnetic target, wherein the at least a first electronic noncontacting magnetic sensor provides a detected measured position of the magnetic target with the controllable field strength generated in relationship to the detected measured position sensed by the at least first electronic noncontacting magnetic sensor.

In an embodiment the invention includes a controllable brake comprising a housing comprising a rotor chamber and a sensor chamber, a shaft, the shaft extending through the rotor chamber and the sensor chamber with an axis of rotation, the shaft having a shaft end, a controllable brake rotor made integral with the shaft, the rotor housed in the rotor chamber, the rotor having a rotation plane, a controllable brake magnetic field generator located in the rotor chamber proximate the controllable brake rotor, the controllable brake magnetic field generator for generating a controllable magnetic field strength, and a controllable brake rotating magnetic target proximate the shaft end, the controllable brake rotating magnetic target housed in the sensor chamber, and a controllable brake first electronic noncontacting magnetic sensor having a first sensor plane, the first electronic noncontacting magnetic sensor mounted in the sensor chamber with the first sensor plane parallel with the controllable brake rotor rotation plane, the first electronic noncontacting magnetic sensor monitoring the rotation of the controllable brake rotating magnetic target and the controllable brake rotor and simultaneously outputting at least two rotational positions of the controllable brake rotor wherein the controllable magnetic field strength generated by the controllable brake magnetic field generator is determined with the rotational positions to control a relative motion of the controllable brake rotor.

In an embodiment the electronic noncontacting magnetic sensor preferably comprises an integrated circuit semiconductor sensor chip with at least two positional outputs. Preferably the electronic noncontacting magnetic sensor integrated circuit semiconductor sensor chip has at least two dies. Preferably the at least two dies are ASICs (Application Specific Integrated Circuits). In a preferred embodiment the at least two dies are side by side dies in the integrated circuit semiconductor sensor chip. In a preferred embodiment the at least two dies are vertically stacked dies in the integrated circuit semiconductor sensor chip. In a preferred embodiment the integrated circuit semiconductor sensor chip ASIC die include a magnetoresistive material, preferably with electrical resistance changes in the presence of the magnetic target magnetic field, preferably with magnetoresistive elements arranged in a Wheatstone bridge. In a preferred embodiment the integrated circuit semiconductor sensor chip ASIC die include a Hall Effect element, preferably a plurality of oriented Hall Effect elements, preferably silicon semiconductor Hall effect elements which detect the magnetic target magnetic field.

It is to be understood that both the foregoing general description and the following detailed description are exemplary of the invention, and are intended to provide an overview or framework for understanding the nature and character of the invention as it is claimed. The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate various embodiments of the invention, and together with the description serve to explain the principals and operation of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which form a part of this specification, illustrate embodiments of the invention.

FIG. 1 is a longitudinal sectional view of a MR device having side coils mounted therein, and having electronics integrated into the brake.

FIG. 2 is a longitudinal sectional view of an MR brake having wrap-around poles for conveying magnetic flux which acts on working surfaces on the periphery of the rotor as well as on a side surface thereof, and also including integrated electronics.

FIG. 3 is a longitudinal sectional view of a drum-style brake having the magnetic field generators positioned for acting on an enlarged outer periphery making up a working surface of the rotor, and comprising integrated electronics within a second chamber and a torsional return-to-center spring incorporated within the chamber housing the rotor.

FIG. 4 is a longitudinal sectional view of a brake similar to that of FIG. 1, but showing the magnetic field generator configured for acting on both surfaces of the rotor, and also showing integrated electronics and how a return-to-center torsional spring can be incorporated within the housing for the electronics.

FIG. 5 is a longitudinal sectional view illustrating an alternative construction of the brake of FIG. 3 showing tapered walls to enhance migration of controllable material away from the shaft, and also showing alternative seal and bearing construction.

FIG. 6 is a cross-sectional view along line 6-6 of FIG. 5 illustrating how a connection between a rotor and a shaft may be made and how backlash between the rotor and the shaft may be allowed and implemented.

FIG. 7A-B show cross section views of a controllable brake.

FIG. 8A-B show cross section views of a controllable brake.

FIG. 8C shows a view of a controllable brake with the circuit board illustrated transparently to show electronic noncontacting magnetic sensors oriented on both sides of the circuit board.

FIG. 9 shows a controllable brake system schematic.

FIG. 10 shows four positional outputs for a controllable brake with two oriented electronic noncontacting magnetic sensors.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Additional features and advantages of the invention will be set forth in the detailed description which follows, and in part will be readily apparent to those skilled in the art from that description or recognized by practicing the invention as described herein, including the detailed description which follows, the claims, as well as the appended drawings.

Reference will now be made in detail to the present preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings.

FIG. 1 illustrates an embodiment of the invention. In an embodiment the invention includes a brake. A brake 11 is illustrated in FIG. 1 with a side coil brake. In embodiments of the invention the term “brake” is used to describe generally a torque generating device that creates a dissipative torque in response to signals received or generated by the brake device 11. For purposes of describing the preferred embodiments of the invention the field controllable material is disclosed as a dry free flowing powder material with particles randomly dispersed throughout the carrier medium. However, it is contemplated that the field controllable medium may also be comprised of a compacted material where the particles are fixed relative to adjacent particles.

Brake 11 includes a housing 13 having a first chamber 15 which houses rotor 21 for rotation therein. Optionally, a second housing chamber 17 is provided and the chamber may enclose any combination of control electronics and control devices comprising for example: sensors for obtaining the displacement or velocity of the rotor 21; an amplifier for increasing the low current signal sent to the field generator 31; controls for communicating with a vehicle operator or a third party located away from the brake, and a communication means for facilitating such external communication. Such control electronics and control devices are represented schematically in FIG. 1 and are identified as 25. The control electronics are used to monitor and/or control operation of device 11. The present invention brake permits control electronics and devices to be located in the brake housing rather than at locations external to the brake. This provides for a compact brake package and it is believed by locating the sensitive control electronics and control devices internally, the electronics and devices are better protected from dirt and particulate matter than with current devices which require the sensitive electronics to be located external of the device housing. As the description proceeds the components located in the second housing chamber may be described generally as “electronics” or “control electronics” for example, however it should be understood that this term should not be limiting and the inventors do not wish to be limited to only electronic type devices. Rather the term referring to the devices and components housed in the second chamber shall more generally be defined and comprised of any suitable means for controlling and or monitoring operation of the device and such means may be comprised of electronic devices and/or mechanical components.

For purposes of describing the first embodiment of the invention, rotor 21 is disk-shaped and is supported on a shaft 23 within the housing 13 for rotation within the housing chamber 15. The rotor includes first and second surfaces and an outer periphery. The surfaces include working portions near the outer periphery at regions on the surface of the rotor upon which the magnetic field acts. The working surface is identified at 42 in FIG. 1. A typical magnetic flux line 37 associated with the applied magnetic field is shown dashed in FIG. 1.

Brake housing 13 includes an open end where the first chamber 15 is located and the open housing end and the chamber is closed and sealed by closing plate 19. The first chamber also contains therein a volume of field controllable material 41 and electromagnetic field generators 29. The field generators comprise, for example, in one configuration, coil 31 and pole piece 33. When activated, the magnetic field generator 29 creates magnetic flux 37. In FIG. 1 the magnetic flux 37 is represented only on one side of the rotor. However the magnetic field acts toroidally around the longitudinal shaft axis and along the entire working surface 42 near the outer periphery of the rotor. The presence of the magnetic field causes the field responsive material 41 to change its rheology resulting in the development of a higher yield stress that must be exceeded to induce onset of shearing of the field responsive material. Typically, in the absence of a magnetic field, the particles return to an unorganized or freely dispersed state and the apparent viscosity or shear flow resistance of the overall material 41 is correspondingly reduced. By activating the magnetic field, the material 41 acts on the working portion 42 of the rotor 21 to inhibit its rotational movement. The stippling that represents material 41 schematically in FIG. 1 is shown in an organized manner in FIG. 1 and the organized arrangement of the particles is a result of the application of field 37. As may be appreciated, supporting the shaft for rotation are bearings 35 which are shown as ball bearings, but may be comprised of any suitable bearing adapted to support rotation of shaft 23.

To keep the field controllable material 41 within the first chamber 15, conventional seal 27 is provided to maintain the material 41 in chamber 15 between plate 19 and pole piece 33. The seal may comprise any suitable seal member adapted to prevent egress of the material from its required location in chamber 15.

The monitoring and controlling electronics and devices 25 housed within the second chamber 17 may include multiple parts such as a rotating disk which is positionally detected by a sensor fixed within the walls of the chamber 17. The sensor may or may not be in contact with the rotating shaft 23. Such a disk may be mounted along the shaft for example through an intermediary sleeve 39.

In brake configuration 11, the magnetic flux 37 generated is substantially perpendicular to surface 42 of the rotor 21, which in this embodiment is shown as a disk, and the magnetic flux is substantially parallel to the shaft 23 as the flux passes through the field controllable material.

In the first embodiment of the invention illustrated in FIG. 1, the disk or rotor 21 is supported by shaft 23 at one shaft end. By supporting the rotor 21 in this manner, a significant portion of the length of the shaft is available to effectively support other components and systems of brake 11. The bearings 35 are located along the shaft length and are spaced apart by an axial distance required to provide rotor stability. As a result of such bearing location and alignment and location, a chamber 17 is defined by the housing 13, bearings 35 and pole pieces 33 wherein various sensors, electronics and other systems may be housed. As a result, brake 11 represents a compact, integrated package generally comprising the required mechanical rotor 21 and shaft 23, field responsive material 41, field generator 29 and monitor and control electronics/sensors 25.

By locating the magnetic field generator 29 along one side of the rotor 21, additional combinations of rotor 21 and field generator 29 may be stacked against the rotor 21 shown in FIG. 1. Any number of additional rotors and field generators may be provided in order to provide the appropriate duplication of magnetic field generators 29 thereby resulting in a brake configuration with multiple disks, suitable for a desired application. Such a brake configuration having a plurality of disks and generators is not illustrated in FIG. 1. Such an alternate configuration would duplicate the FIG. 1 arrangement of rotor 21 and generator 29 in multiple iterations in the direction of end plate 19. Another advantage of first embodiment brake 11 is that by providing a plurality of rotors, the integrated package may be made smaller in the radial disk direction and thus may be more suitable for specific applications where smaller brake configurations are required.

FIG. 2 illustrates a second embodiment of the present invention. The second embodiment magnetic brake 51 is comprised of many of the elements comprising brake 11 of FIG. 1. In this alternate embodiment, brake 51 comprises housing 53 which defines chamber 55 for housing integrated electronics/sensors 59 and also defines chamber 57 for housing rotor 71. Similar to the embodiment shown in FIG. 1, an end plate 19 is provided to close and seal the chamber 57. Although the plate is shown as substantially planar, the plate may also comprise portions that extend substantially perpendicular to the plate and wrap around the housing. Ball bearings 67 serve to support the shaft 69 and conventional seal 87 closes off the first chamber 57 to prevent the field responsive material 85 from migrating from within the chamber 57 toward the bearings 67 and out of the chamber 57. In this alternate embodiment, the rotor 71 is attached to an end of shaft 69 is engaged to the rotor 71 and is rotatable with the shaft. The rotor is not limited to a disk-shaped configuration as will become more readily apparent from the discussion that follows with reference to FIGS. 3 and 5.

As in the case with FIG. 1, a sleeve 65 can be mounted on the shaft 69 and the monitoring and controlling electronics/sensor 59 are shown schematically in greater detail as made up, for example, of two parts 61 and 63. A first part 61 may be fixed within the housing and not fixedly engaged to the sleeve 65. The first part 61 can include monitor and control electronics as well as sensors and/or detectors. Portion 63 can be, for example, a rotating disk 52 mounted on the sleeve 65, the rotation of which is detected by sensors mounted on the fixed part 61. Thus, the rotation of the shaft 69 and rotor 71 can be detected to allow appropriate control of electromagnetic field generator 73.

In the second embodiment brake 51, the electromagnetic field generator 73 may include an electromagnetic coil 75 and a pole piece configuration that is slightly different than the configuration of FIG. 1. Turning to FIG. 2, the pole configuration includes a first radially extending pole portion 77 and a second axially extending pole portion 79. The second pole portion extends axially between radially extending pole portion 77 and plate 19. Respective gaps 74 and 76 separate the outer periphery of the rotor 71 and the second pole portion 79 and the working surface 42 and the first pole portion 77. When a current is supplied to the coil 75, the field generator is activated and thereby generates magnetic flux 81, represented dashed in FIG. 2, which acts on field responsive material that fills the chamber 57 and gaps 74 and 76. The field 81 changes the rheology of the material causing the material to act upon the rotor outer periphery and surface 42 and thereby provide resistance to the motion of the rotor 71. Like brake 11 of FIG. 1, although a single rotor 71/generator 73 combination is shown in FIG. 2, brake 51 may comprise any suitable number of rotor/generator combinations required to supply the requisite braking forces. The benefits associated with the first embodiment brake recited hereinabove are also realized with the second embodiment brake 51.

A third embodiment brake of the present invention is illustrated in FIG. 3 and is referred to generally at 101. Brake 101 comprises hollow, cylindrical housing 103 which defines a first chamber 113 for housing a rotor 107 for rotation therein about axis 99 and defines second chamber 111 which houses monitoring and/or controlling electronics 115 in the manner previously described. The first chamber also houses a volume of a field responsive material 135. The rotor is a drum-shaped rotor that comprises a substantially I-shaped cross section with a wide outer annular peripheral portion 108 joined by a narrow web 112. The rotor 107 is fixed in a conventional manner to one end of shaft 105 which in turn is supported by bearings 133 along the shaft length and generally in the manner previously described with first and second embodiment brakes 11 and 51. Closing plate 109 serves to seal and close one end of the housing 103. Plate 114 closes and seals the opposite housing end. The rotor may have any suitable cross section and other suitable configurations may comprise a C-shaped cross section and an L-shaped cross section for example.

The monitor and/or control electronics 115, in exemplary form, can include a combination of rotating disks having appropriate notches or other detectable indicia thereon. The rotating disks 117 may be mounted on a sleeve 118 fixed to shaft 105. Other components 119 of the electronics 115 can be fixed within the chamber 111 in a manner so that the components surround the sleeve and are not in contact with the sleeve 118. In this way, the components 119 do not rotate with the sleeve 118. Sensors or brushes schematically represented at 121 may be mounted on member 119 to detect relative rotation of disk 117.

In the embodiment of FIG. 3, the seal 132 required to prevent migration of material 135 from the first chamber 113 to the second chamber 111 is shown seated in bearing support plate 116. Such a suitable seal may comprise the seal disclosed in the description of first and second embodiment brakes. The suitable conventional seal may be supported in the bearing support plate 116 or within bearings 133. An annular shroud 120 is located between plates 114 and 116. Shroud 120, in combination with plates 114 and 116 encloses the sensing means 115 within chamber 111.

Returning again to the rotor 107 of the third embodiment brake 101, rotor 107 is not substantially disk-shaped like disks 21 and 71 previously described. As shown in FIG. 3, rotor enlarged peripheral portion 108 is located proximate electromagnetic coil 125 of field generator generally identified at 123. As shown by the stippling representing field responsive material 135, an annular gap 122 separates the portion 108 and field generator and the gap 122 is substantially filled with a volume of the field controllable material 135. The magnetic field produced by field generator 123 extends through material 135 and the portion of the rotor identified at 108. The magnetic field is illustrated by magnetic field 129 represented as dashed in FIG. 3.

The magnetic field generator 123 generally comprises an electromagnetic coil 125 and pole pieces 127 which in combination generate an electromagnetic flux represented by dashed field lines 129 which extend through the material 135 in a direction that is substantially perpendicular to shaft 105 and to the periphery of the rotor 107. As shown in FIG. 3 the field generator is located radially outwardly from the rotor 107.

The third embodiment brake 101 comprises a return-to-center acting device, such as a torsion or torsional center-return spring 131 which is mounted within first housing chamber 113. Other center return devices may comprise bungee cords or other type elastic components. Generally the suitable center return device is any device that stores energy as the rotor and/or shaft are/is displaced from a center or start position or orientation and then at a particular displacement releases the stored energy to return the rotor and shaft to the start orientation. The particular displacement that results in a release of the stored energy may comprise for example, the operator releasing the shaft or rotor or the shaft or rotor reaching a maximum angular displacement. The torsion return spring 131 typically assumes a torque free condition at the center position of a device with which brake 101 may be associated, such as a steering wheel at the center position of the device. The return to center member is conventionally fixed at its ends to both the rotor 107, and end plate 109 so as to exert a progressively increasing return torque to center position upon the turning of the device with which the brake is associated, for example, a wheel. The return-to-center device may comprise a number of devices and attachment configurations.

FIG. 4 illustrates a fourth embodiment brake 201 similar to the first embodiment brake 11. In the fourth embodiment brake, the brake housing 203 includes a first chamber 215 wherein rotor 219 is located for rotation therein and the rotor is fixed to one end of shaft 209. The chamber 215 includes a volume of a field responsive material 217 therein. Conventional seal 213 seals the chamber 215 by preventing the field controllable material from migrating out of the chamber 215. Plate 207 closes the chamber 215 after the brake 201 is fully assembled. Bearings 211 support shaft 209 away from the shaft end supporting the rotor 219. The housing 203 also defines a second chamber 205 for housing the monitoring and control electronics and devices. The control means is represented schematically and referenced at 229 in FIG. 4. A torsion return spring 231 may be provided within the second chamber 205, fixedly secured at the spring ends to an internal wall of the second chamber 205, and to a sleeve 232 upon which portions of the control means 229 may be also mounted for rotation therewith. The sleeve is made integral with the shaft 209 for rotation therewith.

In the embodiment of the invention illustrated FIG. 4, the magnetic field generator 221 comprises an annular pole piece 225 having a U-shaped cross section and an electromagnetic coil 223 located within the open portion of the pole piece and radially outwardly from and adjacent to the outer periphery of the disk-shaped rotor 219. The pole piece 225 could be comprised of separate pole pieces for ease of assembly and manufacture. As shown in FIG. 4, the legs or side portions of the poles 225 a and 225 b extend toward the central longitudinal axis of rotation of shaft 209 and adjacent the rotor working surfaces 219 a and 219 b. Gaps separate the pole piece legs 225 a, 225 b and electromagnet 223 from the rotor 219 and field controllable material 217 substantially fills the gaps. The magnetic flux line 227 represented as dashed in FIG. 4, causes the rheology of material 217 to change thereby producing a torque dissipating force that acts on the working surfaces 219 a, 219 b of the rotor 219 to impede rotation thereof.

A fifth embodiment brake 301 is disclosed in FIG. 5 and the fifth embodiment brake is similar to the embodiment of FIG. 3.

The fifth embodiment brake comprises a housing 303 having a chamber 305 for housing control means such as integrated control electronics or control devices and such is identified schematically at 311. Shaft 309 extends through second chamber 305 and into a first chamber 307 and the rotor 315 is supported on the shaft end in the first chamber 307. The chamber 307 is closed and sealed at the axial ends by plates 351 and 371. In the fifth embodiment of the invention the rotor 315, is a “drum-style” rotor similar to the rotor illustrated in the third embodiment of FIG. 3. The rotor comprises a wide annular outer periphery joined by a relatively narrow web. The shaft 309 is supported for rotation away from the rotor by two bearings 313, which for purposes of the present invention are conventional “dry shaft” bearings which are a suitable alternative to the roller bearings illustrated in the previous embodiments. In this fifth embodiment of the invention, the shaft 309 is suitably supported to sustain axial loading and to prevent axial movement of the loaded shaft. A conventional thrust bearing thrust bearing 317 of conventional construction is provided along shaft 309 between rotor 315 and bearing 313 to support the axial shaft loads.

The magnetic field generator 350 is located radially outwardly from the outer periphery of the rotor 315. The field generator comprises annular pole pieces 327 that enclose an electromagnetic coil 325 which in combination with field responsive material 319 and rotor periphery produce an electromagnetic flux represented by flux lines 329 represented as dashed in FIG. 5. As shown in FIG. 5 the field responsive material is located in the annular gap separating the outer periphery of the rotor and the field generator.

In the fifth embodiment brake 301, the plates 351 and 371 that close the axial ends of chamber 307 comprises tapered inner walls 331 and 333 respectively. As shown in FIG. 5, the walls generally taper outwardly from the axis of rotation 373. In this way, the chamber narrows progressively as the distance from the axis decreases and, conversely, the chamber widens progressively as the distance from the axis increases. The maximum axial dimension of the chamber occurs proximate the rotor outer periphery and field generator 350. As a result of the foregoing chamber taper, the shear rate of the field responsive material can be made substantially constant or increase as the distance from the axis increases and the axial chamber dimension decreases such that migration of controllable material 319 is promoted in the direction of arrow 335 away from seals 321. The seal 321 in this embodiment can take the shape of v-seals which provide a material-free region between an extension of the seal 321 which slides against the surface of rotor 315 as it rotates, preventing material from contacting the bearing 313, in this case dry shaft bearing 313. Other face seal and lip seal configurations can be used in this region. Similarly, a well structure 314 as shown, creates a tortuous path tending to keep the material away from the seals 321.

FIG. 6 illustrates in cross-sectional view along lines 6-6 of FIG. 5 and represents one arrangement for connecting the shaft 309 and rotor 315. As shown in FIG. 6, shaft 309 is shaped as a rectangle at the region of the rotor 315 to fit within a mating square-shaped aperture within the rotor. It is possible in such a configuration to allow for relative slippage or backlash between the shaft 309 and the rotor 315. In some cases it may be desirable to allow for such slippage or backlash. For example, when the device with which the brake is associated has reached its end-of-motion point and the electromagnetic field is at full strength, such slippage or backlash may be desirable to allow a relatively small movement of the shaft 309 without movement of the rotor being detected by a sensor of the control means which would trigger a reduction of the electromagnetic field thereby allowing an operator to move the device associated with the brake away from the end-of-motion position. In this way the device could be displaced away from the end of motion position without first having to overcome the strong material shear stress associated with being at the end of travel location. While a square arrangement is shown, it will be appreciated that other configurations, such as a grooved circular cross section such as a splined shaft and grooved engagement surfaces on the rotor, slightly mismatched in dimension, can provide a similar function, as well as other arrangements as will be readily apparent to those of ordinary skill in the art.

As will also be readily apparent to those of ordinary skill in the art, the various features of the various embodiments can be interchanged as may be appropriate for the particular configuration, by providing a brake in which the rotor is supported by a shaft on one side only and having two bearings to support the shaft, in all cases a cavity can be created in which, in one housing can be housed various sensors, control means electronics and other items that the system may require in an integrated package.

In an embodiment the invention includes a controllable brake. The controllable brake preferably includes a housing including a first chamber and a second chamber. The controllable brake preferably includes a shaft, the shaft extending through the first chamber and the second chamber with an axis of rotation, the shaft having a first shaft end. The controllable brake preferably includes a controllable brake rotor made integral with the shaft, the rotor housed in the first chamber, with the rotor having a rotation plane preferably normal to the axis of rotation. The controllable brake preferably includes a controllable brake magnetic field generator located in the first chamber proximate the controllable brake rotor, the controllable brake magnetic field generator for generating a controllable magnetic field strength. The controllable brake preferably includes a controllable brake rotating magnetic target integrated with the shaft proximate the first shaft end, the controllable brake rotating magnetic target housed in the second chamber. The controllable brake preferably includes a controllable brake electronics circuit board mounted in the second chamber, the controllable brake electronics circuit board having a control board plane, the control board plane oriented normal to the shaft axis of rotation. The controllable brake preferably includes a first electronic noncontacting magnetic sensor having a first sensor plane, the first electronic noncontacting magnetic sensor integrated on the controllable brake electronics circuit board with the first sensor plane parallel with the control board plane. The controllable brake preferably includes a second electronic noncontacting magnetic sensor having a second sensor plane, the second electronic noncontacting magnetic sensor integrated on the controllable brake electronics circuit board with the second sensor plane parallel with the control board plane with the control board plane between the first sensor plane and the second sensor plane, the first electronic noncontacting magnetic sensor and the second electronic noncontacting magnetic sensor monitoring the rotation of the controllable brake rotating magnetic target and outputting a rotational position of the controllable brake rotating magnetic target wherein the controllable magnetic field strength generated by the controllable brake magnetic field generator is determined by the rotational position to control a relative motion of the controllable brake rotor.

In preferred embodiments the electronic noncontacting magnetic sensors preferably comprise integrated circuit semiconductor sensor chips with at least two positional outputs. Preferably the electronic noncontacting magnetic sensor integrated circuit semiconductor sensor chip has at least two dies. Preferably the at least two dies are ASICs (Application Specific Integrated Circuits). In a preferred embodiment the at least two dies are side by side dies in the integrated circuit semiconductor sensor chip. In a preferred embodiment the at least two dies are vertically stacked dies in the integrated circuit semiconductor sensor chip. In a preferred embodiment the integrated circuit semiconductor sensor chip ASIC die include a magnetoresistive material, preferably with electrical resistance changes in the presence of the magnetic target magnetic field, preferably with magnetoresistive elements arranged in a Wheatstone bridge. In a preferred embodiment the integrated circuit semiconductor sensor chip ASIC die include a Hall Effect element, preferably a plurality of oriented Hall Effect elements, preferably silicon semiconductor Hall effect elements which detect the magnetic target magnetic field.

The controllable brake 500 preferably includes a housing 502. The housing 502 preferably includes a first sealed chamber 504 and a second sealed chamber 506. The controllable brake preferably includes a shaft 512 with an axis of rotation 516 and a first shaft end 514. Preferably the shaft extends through the first sealed chamber and the second sealed chamber. The controllable brake 500 preferably includes a controllable brake rotor 508 made integral with the shaft, with the rotor 508 housed in the first sealed chamber 504, with the rotor 508 having a rotation plane 570 preferably normal to the axis of rotation 516. The controllable brake 500 preferably includes a controllable brake magnetic field generator 510 located in the first chamber proximate the controllable brake rotor 508, the controllable brake magnetic field generator for generating a controllable magnetic field strength. The controllable brake preferably includes a controllable brake rotating magnetic target 518 made integral with the shaft proximate the first shaft end 514 with the controllable brake rotating magnetic target 518 housed in the second sealed chamber, and a controllable brake electronics circuit board 520 mounted in the second sealed chamber. Preferably the brake operation electronics control board 520 controls and/or monitors the operation of the controllable brake 500. The controllable brake electronics circuit board 520 having a control board plane 522, the control board plane 522 oriented normal to the axis of rotation 516, a first electronic noncontacting magnetic sensor 524 having a first sensor plane 526, the first electronic noncontacting magnetic sensor 524 integrated on the controllable brake electronics circuit board 520 with the first sensor plane 526 parallel with the control board plane 522, and a second electronic noncontacting magnetic sensor 528 having a second sensor plane 530, the second electronic noncontacting magnetic sensor 528 integrated on the controllable brake electronics circuit board 520 with the second sensor plane 530 parallel with the control board plane 522 with the control board plane 522 between the first sensor plane 526 and the second sensor plane 530, the first electronic noncontacting magnetic sensor 524 and the second electronic noncontacting magnetic sensor 528 monitoring the rotation of the controllable brake rotating magnetic target 518 and outputting a rotational position of the controllable brake rotating magnetic target wherein the controllable magnetic field strength generated by the controllable brake magnetic field generator 510 is determined by the rotational position to control a relative motion of the controllable brake rotor 508. The controllable brake preferably includes a field responsive controllable material 532 sealed in the first chamber 504, preferably with the rheology of the field responsive controllable material being affected by the magnetic field generator 510. Preferably the electronic noncontacting magnetic sensors 524, 528 monitor the rotation of the rotating magnetic target 518, preferably with the magnetic sensors 524, 528 oriented and mounted relative to the shaft end 514 and its axis of rotation 516. Preferably the electronic noncontacting magnetic sensors 524, 528 are substantially planar sensors, with their sensor plane normal to axis of rotation 516, with the axis 516 centrally intersecting the sensing centers of the sensors 524, 528 with the sensor's sensing centers aligned with the axis 516. Preferably the magnetic target 518 is at the end of the shaft, preferably with the magnetic target 518 comprised of a magnet with north and south poles oriented relative and normal to the shaft axis of rotation 516 with the opposed N and S poles separated by the axis of rotation 516. Preferably the field responsive controllable material 532 is comprised of magnetic metal ferrous particles and lubricant, preferably dry ferrous particles and dry lubricant (preferably dry molybdenum disulfide). Preferably the controllable brake rotating magnetic target 518 is a permanent magnet with a north pole (N) and a south pole (S) opposed along a north south axis 534, with the north south axis 534 perpendicular with the shaft axis of rotation 516. Preferably the controllable brake 500 includes field responsive controllable material 532 sealed in the first chamber 504, with the field responsive controllable material 532 being affected by the controllable magnetic field strength, and the magnetic field generator 510 is adapted to generate a magnetic flux in a direction through the field responsive controllable material 532 towards the rotor 508, and the controllable brake electronics circuit board 520 provides a controlled current to the magnetic field generator 510. Preferably the controllable brake 500 includes a field responsive controllable material 532 sealed in the first chamber 504 with a rheology of the field responsive controllable material 532 being affected by the controllable magnetic field strength, and the magnetic field generator 510 is adapted to generate a magnetic flux 536 in a direction through the field responsive controllable material 532 towards the rotor 508, and the controllable brake electronics circuit board 520 provides a controlled current 538 to the magnetic field generator 510. Preferably the controllable brake shaft 512 is supported for rotation about axis 516 by bearings 540 in the housing 502, and further including seals 542 for sealing the first chamber to retain the controllable material 532 therein, preferably with the first and second chambers sealed from each other with the seals 542 and the housing members to provide the first and second separate sealed chambers 504,506, preferably with the field generator 510, including a pole piece member 544 which provides for both the generation of a magnetic field with an electromagnetic coil 546 and a housing divider for separating the housing 502 into the first and second chambers. Preferably the magnetic field generator 510 includes an electromagnetic coil 546 and the controllable brake electronics circuit board 520 is electrically connected with the magnetic field generator electromagnetic coil 546, preferably with electrical contact connections leads 548 to the EM coil 546. Preferably the electronics circuit board 520 provides a current 538 (i) to EM coil 546, for applying magnetic field flux 536 whose strength is determined by the rotational position of the rotor 508, with the magnetic target 518 rotation angle sensed by the sensors 524, 528. In a preferred embodiment at least one of the electronic noncontacting magnetic sensors 524,528 include a magnetoresistive material, preferably with electrical resistance changes in the presence of the magnetic target 518 magnetic field, preferably with magnetoresistive elements arranged in a Wheatstone bridge. In a preferred embodiment at least one of the electronic noncontacting magnetic sensors 524,528 include a Hall Effect element, preferably a plurality of oriented Hall Effect elements, preferably silicon semiconductor Hall effect elements.

In a preferred embodiment the electronic noncontacting magnetic sensor includes a magnetoresistive material, preferably with electrical resistance changes in presence of a sensed magnetic field, preferably with magnetoresistive elements arranged in a Wheatstone bridge integrated circuit sensor chip with a planar format providing a sensor plane. In a preferred embodiment the electronic noncontacting magnetic sensor includes a Hall Effect element, preferably a plurality of oriented Hall Effect elements, preferably silicon semiconductor Hall effect elements arranged in an integrated circuit sensor chip with a planar format providing a sensor plane.

In an embodiment the invention includes a controllable brake. The controllable brake preferably includes a rotating magnetic target. The controllable brake preferably includes a magnetically permeable rotor. The controllable brake preferably includes a shaft connected to the magnetically permeable rotor. The controllable brake preferably includes a housing having a first housing chamber rotatably housing the magnetically permeable rotor therein, and including a magnetic field generator spaced from the magnetically permeable rotor, and configured and positioned for generating a controllable magnetic field to control a relative motion of the magnetically permeable rotor, and a second housing chamber containing control electronics therein, the second housing chamber electronics including at least a first oriented electronic noncontacting magnetic sensor, the at least first oriented electronic noncontacting magnetic sensor oriented relative to the rotating magnetic target and the shaft wherein the at least first oriented electronic noncontacting magnetic sensor monitors the rotation of the rotating magnetic target.

Preferably the controllable brake 500 includes rotating magnetic target 518. The controllable brake 500 preferably includes magnetically permeable rotor 508. The controllable brake preferably includes shaft 512 connected to the magnetically permeable rotor 508. The controllable brake preferably includes housing 502 having a first housing chamber 504 rotatably housing the magnetically permeable rotor 508 therein, and including a magnetic field generator 510 spaced from the magnetically permeable rotor 508, and configured and positioned for generating a controllable magnetic field 536 to control a relative motion of the magnetically permeable rotor 508, and a second housing chamber 506 containing control electronics 520 therein, the second housing chamber electronics 520 including at least a first oriented electronic noncontacting magnetic sensor 524, the at least first oriented electronic noncontacting magnetic sensor oriented relative to the rotating magnetic target 518 and the shaft 512 wherein the at least first oriented electronic noncontacting magnetic sensor monitors the rotation of the rotating magnetic target 518. Preferably the brake includes a controllable material 532, preferably contained in the first chamber 504 between and preferably filling the space between the magnetically permeable rotor 508 and the magnetic field generator 510 with the magnetic field generator spaced from the magnetically permeable rotor with the controllable material in-between the two with the two configured and positioned for generating a controllable magnetic field 536 to control the relative motion of the magnetically permeable rotor 508 relative to the magnetic field generator 510 with the magnetic field flux 536 through the controllable material 532 sealed in the first chamber between the magnetically permeable rotor and magnetic field generator controlling the relative motion. Preferably the at least first electronic noncontacting magnetic sensor provides a detected measured rotational position of the rotor, and the circuit board 520 control electronics are electrically connected with the magnetic field generator 510 and provide electrical control of the magnetic field generator 510 to apply a magnetic field 536 whose strength is determined by the detected measured rotational position of the rotor. Preferably the circuit board 520 control electronics electrical contact connections leads 548 deliver a current 538 to the EM coil 546, preferably with the electronics circuit board providing current i to EM coil 546 for applying magnetic field 536 whose strength is determined by the relative rotational position of the rotor 508 as the magnetic target rotation angle sensed by the at least one noncontact oriented senor. Preferably the at least first oriented electronic noncontacting magnetic sensor is integrated into brake operation electronics control board 520 mounted in the second sealed chamber 506 wherein the brake operation electronics control board 520 controls the operation of the controllable brake 500. Preferably the noncontacting magnetic sensor has a sensor plane 526, 530 oriented with the shaft axis of rotation 516, preferably with the sensor plane parallel with control board plane 522 with such normal to shaft axis of rotation 516, with the rotation axis 516 intersecting the sensor plane proximate the sensing center of the noncontacting magnetic sensor. Preferably the controllable brake 500 includes a second oriented electronic noncontacting magnetic sensor 528, wherein the first electronic noncontacting magnetic sensor 524 and the second electronic noncontacting magnetic sensor 528 are integrated into brake operation electronics control board 520 mounted in the second sealed chamber 506 wherein the brake operation electronics control board 520 controls and/or monitors the operation of the controllable brake 500. Preferably the at least first and second magnetic sensors 524, 528 have a sensor planes oriented with the shaft axis of rotation 516, preferably with the sensor planes parallel with control board plane 522, with such planes normal to shaft axis of rotation, with the control board plane 522 between the first and second sensor planes 526 and 530. Preferably the brake operation electronics control circuit board 520 has a less than one millimeter thickness between the first oriented electronic noncontacting magnetic sensor 524 and the second oriented electronic noncontacting magnetic sensor 528, and the rotating magnetic target 518 is comprised a shaft oriented permanent magnet, preferably with permanent magnet N-S pole axis 534. Preferably the magnetic sensors have sensor planes oriented with the shaft axis of rotation 516, preferably with the sensor planes parallel with the control board plane, with such normal to the shaft axis of rotation, with the control board plane of the less than one millimeter thickness circuit board between the first and second sensor planes.

In an embodiment the invention includes a method of controlling motion. The method preferably includes providing a housing having a first housing chamber and a second housing chamber. The method preferably includes providing a shaft with a magnetically permeable rotor, the shaft including a rotating magnetic target distal from the magnetically permeable rotor. The method preferably includes providing a magnetic field generator for generating a magnetic field with a controllable field strength for controlling a relative motion of the magnetically permeable rotor. The method preferably includes providing at least a first electronic noncontacting magnetic sensor, the at least first electronic noncontacting magnetic sensor integrated on an operation electronic control board having a control board plane. The method preferably includes disposing the magnetically permeable rotor and the magnetic field generator in the first housing chamber. The method preferably includes disposing the rotating magnetic target and the at least a first electronic noncontacting magnetic sensor in the second housing chamber, wherein the operation electronic control board is in electrical communication with the magnetic field generator and the control board plane is oriented relative to the rotating magnetic target, wherein the at least first electronic noncontacting magnetic sensor provides a detected measured rotational position of the rotating magnetic target with the controllable field strength generated in relationship to the detected measured rotational position sensed by the at least first electronic noncontacting magnetic sensor.

Preferably the controlling motion method includes providing a housing 502 having a first housing chamber 504 and a second housing chamber 506. Preferably the controlling motion method includes providing a shaft 512 with a magnetically permeable rotor 508, with the shaft including a rotating magnetic target 518 distal from the magnetically permeable rotor 508. Preferably the controlling motion method includes providing a magnetic field generator 510 for generating a magnetic field with a controllable field strength for controlling a relative motion of the magnetically permeable rotor. Preferably the controlling motion method includes providing a field responsive controllable material, with the field responsive controllable material affected by the magnetic field generator magnetic field. Preferably the provided field responsive controllable material has a rheology which is controllable by the generated magnetic field, preferably with a field responsive controllable material 532 provided from magnetic metal ferrous particles and lubricant, preferably dry ferrous particles and dry lubricant (preferably dry molybdenum disulfide lubricant). Preferably the controlling motion method includes providing at least a first electronic noncontacting magnetic sensor 524, 528. Preferably the at least first electronic noncontacting magnetic sensor is integrated on an operation electronic control board 520 having a control board plane 522. Preferably the controlling motion method includes disposing the magnetically permeable rotor, the magnetic field generator, in the first housing chamber. Preferably disposing the magnetically permeable rotor, the magnetic field generator, in the first housing chamber includes sealing such therein along with the field responsive controllable material 532. Preferably the controlling motion method includes disposing the rotating magnetic target 518 and the at least a first electronic noncontacting magnetic sensor in the second housing chamber 506, wherein the operation electronic control board 520 is in electrical communication with the magnetic field generator 510 and the control board plane 522 is oriented relative to the rotating magnetic target 518, wherein the at least first electronic noncontacting magnetic sensor provides a detected measured rotational position of the rotating magnetic target with the controllable field strength generated in relationship to the detected measured rotational position sensed by the at least first electronic noncontacting magnetic sensor. Preferably the at least first electronic noncontacting magnetic sensor has the sensor plane (526, 530) oriented with the control board plane 522. Preferably the sensor plane (526,530) is parallel with control board plane 522, with such normal to shaft axis of rotation 516, with rotation axis 516 intersecting the sensor plane proximate the sensing center of the sensor. Preferably the method includes providing a second electronic noncontacting magnetic sensor with a sensor plane (526, 530) with the second electronic noncontacting magnetic sensor integrated on the operation electronic control board with the second electronic noncontacting magnetic sensor plane oriented parallel with the control board plane, with the control board plane between the second electronic noncontacting magnetic sensor plane and the first electronic noncontacting magnetic sensor plane. In an embodiment preferably at least one of the electronic noncontacting magnetic sensor includes a magnetoresistive material, preferably with electrical resistance changes in presence of the target magnetic field, preferably with magnetoresistive elements arranged in a Wheatstone bridge. In an embodiment preferably at least one of the electronic noncontacting magnetic sensor includes a Hall Effect element, preferably a plurality of oriented Hall Effect elements, preferably silicon semiconductor Hall effect elements for sensing shaft rotational changes of the target magnetic field.

In an embodiment the invention includes a method of making a motion control brake for controlling motion. The method preferably includes providing a magnetic field generator for generating a magnetic field with a controllable field strength for controlling a relative motion of a movable brake member. The method preferably includes providing a magnetic target which moves with the relative motion of the movable brake member. The method preferably includes providing an electronic circuit board having a circuit board plane, a first oriented electronic noncontacting magnetic sensor having a first oriented sensor plane, the first electronic noncontacting magnetic sensor integrated on the electronic circuit board with the first sensor plane parallel with the circuit board plane, a second oriented electronic noncontacting magnetic sensor having a second oriented sensor plane, the second electronic noncontacting magnetic sensor integrated on the electronic circuit board with the second sensor plane parallel with the circuit board plane with the circuit board plane between the second sensor plane and the first sensor plane. The method preferably includes disposing the electronic circuit board proximate the magnetic target wherein the first electronic noncontacting magnetic sensor and the second electronic noncontacting magnetic sensor provide a detected measured magnetic target position with the controllable field strength generated by the magnetic field generator determined by the detected measured magnetic target position.

Preferably the method of making a motion control brake 500 includes providing a magnetic field generator 510 for generating a magnetic field 536 with a controllable field strength for controlling a relative motion of a movable brake member 508. The method preferably includes providing a magnetic target 518 which moves with the relative motion of the movable brake member 508. The method preferably includes providing an electronic circuit board 520 having a circuit board plane 522, a first oriented electronic noncontacting magnetic sensor 524 having a first oriented sensor plane 526, the first electronic noncontacting magnetic sensor 524 integrated on the electronic circuit board 520 with the first sensor plane 526 parallel with the circuit board plane 522, a second oriented electronic noncontacting magnetic sensor 528 having a second oriented sensor plane 530, the second electronic noncontacting magnetic sensor 528 integrated on the electronic circuit board 520 with the second sensor plane 530 parallel with the circuit board plane 522 with the circuit board plane 522 between the second sensor plane 530 and the first sensor plane 526. The method preferably includes disposing the electronic circuit board 520 proximate the magnetic target 518 wherein the first electronic noncontacting magnetic sensor 524 and the second electronic noncontacting magnetic sensor 528 provide a detected measured magnetic target position with the controllable field strength generated by the magnetic field generator 510 determined by the detected measured magnetic target position. Preferably the movable brake member is comprised of a movable brake rotor 508, preferably with a shaft 512 having a distal end permanent magnet magnetic target 518 which moves with the relative motion of the movable brake rotor. Preferably the electronic circuit board first integrated oriented electronic noncontacting magnetic sensor 524 and its first oriented sensor plane parallel with the circuit board plane and the second integrated oriented electronic noncontacting magnetic sensor 528 with its second oriented sensor plane parallel with the circuit board plane with the circuit board plane between the second sensor plane and the first sensor plane, with the method including the integrating and orienting the two sensors overlappingly on both planar sides of the circuit board 520. Preferably the overlapping integrated and oriented sensors and in between circuit board are disposed proximate the magnetic target 518 wherein the first electronic noncontacting magnetic sensor 524 and the second electronic noncontacting magnetic sensor 528 provide a detected measured magnetic target position with the controllable field strength generated by the magnetic field generator 510 determined by the detected measured magnetic target position. The method preferably includes providing a shaft 512 with the movable brake member comprising rotor 508 and the magnetic target 518 includes a permanent magnet with a north pole and a south pole opposed along a north south axis 534, preferably with the north south axis 534 perpendicular with the shaft axis of rotation 516, preferably with the movable brake member rotor 508 made integral with the shaft 512 and the magnetic target permanent magnet 518 made integral with the shaft. Preferably the integrating the shaft and rotor includes connecting the rotor with the shaft in a manner to restrain relative rotation there between. Preferably the shaft, the movable brake member rotor, and the magnetic target permanent magnet have an axis of rotation 516 with the circuit board plane 522 oriented normal to the axis of rotation 516 with the axis of rotation going through the sensor centers, preferably with the north south axis 534 perpendicular with the shaft axis of rotation 516. Preferably the electronic circuit board 520 has a less than one millimeter thickness between the first oriented electronic noncontacting magnetic sensor 524 and the second oriented electronic noncontacting magnetic sensor 528, and preferably the rotating magnetic target 518 is comprised of a shaft oriented permanent magnet. Preferably the first electronic noncontacting magnetic sensor 524 and the second electronic noncontacting magnetic sensor 528 provide the circuit board with at least a first position output, at least a second position output, and at least a third position output, and most preferably four simultaneously detected position outputs, with the motion control brake method/system including a position output processor for processing the multiply position outputs, preferably with the position output processor comparing the multiply outputs to determine if there is a suspected error output and exclude such suspected error output from the determination of the magnetic field generated to actively control motion with the brake. Preferably the controllable brake provides a multiply redundancy controllable brake sensor system with the brake sensors at least three simultaneously sensed positions outputs monitored and compared for suspected error output, with error outputs excluded from the electronic control system determination of controlling the applied magnetic field to control the relative motion allowed by the brake, either within an inner control loop operating within the brake or an outer control loop within which the brake is integrated to provide the brake's control of motion and outputted target sensed positions. In an embodiment the electronic noncontacting magnetic sensors include magnetoresistive materials with electrical resistance changes in the presence of the magnetic target magnetic field, preferably with sensor magnetoresistive elements arranged in a Wheatstone bridge to sense the rotating magnetic field of the magnetic targets pole axis 534. In an embodiment the electronic noncontacting magnetic sensors include a Hall Effect element, preferably a plurality of oriented Hall Effect elements, preferably silicon semiconductor Hall effect elements integrated together to sense the rotating magnetic field of the magnetic targets pole axis 534.

In an embodiment the invention includes a method of making a control system. The method preferably includes providing a control system rotating magnetic target having an axis of rotation. The method preferably includes providing a control system electronic circuit board having a circuit board plane and a first circuit board side and an opposite second circuit board side, a first oriented electronic noncontacting magnetic sensor integrated on the electronic circuit board first circuit board side, a second oriented electronic noncontacting magnetic sensor integrated on the electronic circuit board second circuit board side. The method preferably includes disposing the control system electronic circuit board proximate the control system rotating magnetic target with a projected extension of the axis of rotation extending through the first oriented electronic noncontacting magnetic sensor and the second oriented electronic noncontacting magnetic sensor wherein the first electronic noncontacting magnetic sensor and the second electronic noncontacting magnetic sensor provide a plurality of detected measured magnetic target rotary position outputs.

Preferably the method of making a control system includes providing a control system rotating magnetic target 518 having an axis of rotation 516. The method preferably includes providing a control system electronic circuit board 520 having a circuit board plane 522 and a first circuit board side 521′ and an opposite second circuit board side 521″, a first oriented electronic noncontacting magnetic sensor 524 integrated on the electronic circuit board first circuit board side 521′, a second oriented electronic noncontacting magnetic sensor 528 integrated on the electronic circuit board second circuit board side 521″. The method preferably includes disposing the control system electronic circuit board 520 proximate the control system rotating magnetic target 518 with a projected extension of the axis of rotation 516 extending through the first oriented electronic noncontacting magnetic sensor 524 and the second oriented electronic noncontacting magnetic sensor 528 wherein the first electronic noncontacting magnetic sensor 524 and the second electronic noncontacting magnetic sensor 528 provide a plurality of detected measured magnetic target rotary position outputs. Preferably the method includes integrating and orienting the two sensors overlappingly on both planar sides of the circuit board 520. Preferably overlapping, integrating and orienting the sensors on the circuit board such that the circuit board is mountable proximate the magnetic target 518 wherein the first electronic noncontacting magnetic sensor 524 and the second electronic noncontacting magnetic sensor 528 provide a plurality of simultaneously detected measured magnetic target position outputs. Preferably the magnetic target 518 includes a permanent magnet with a north pole and a south pole opposed along a north south axis 534 with the north south axis perpendicular with the axis of rotation 516, preferably with the overlapping, integrated oriented sensors 524, 528, preferably providing at least a first position output, at least a second position output, and at least a third position output, and most preferably four simultaneously detected position outputs, with the motion control system including a position output processor for processing the multiply position outputs, preferably with the position output processor comparing the multiply outputs to determine if there is a suspected error output and exclude such suspected error output from the control system process loop. Preferably the control system provides a multiply redundancy control sensor system with the sensors at least three simultaneously sensed positions outputs monitored and compared for suspected error output, with error outputs excluded from the electronic control system determination control loops (either within an inner control loop operating within the control system electronic circuit board 520 or an outer control loop within which the board is integrated into to provide the outputted target sensed positions. In an embodiment the electronic noncontacting magnetic sensors include magnetoresistive materials with electrical resistance changes in the presence of the magnetic target magnetic field, preferably with sensor magnetoresistive elements arranged in a Wheatstone bridge to sense the rotating magnetic field of the magnetic targets pole axis 534. In an embodiment the electronic noncontacting magnetic sensors include a Hall Effect element, preferably a plurality of oriented Hall Effect elements, preferably silicon semiconductor Hall effect elements integrated together to sense the rotating magnetic field of the magnetic targets pole axis 534. Preferably the electronic circuit board 520 has a less than one millimeter thickness between the first oriented electronic noncontacting magnetic sensor and the second oriented electronic noncontacting magnetic sensor, and preferably the rotating magnetic target includes a shaft oriented permanent magnet.

Preferably the first electronic noncontacting magnetic sensor and the second electronic noncontacting magnetic sensor provide the circuit board 520 with at least a first position output, at least a second position output, and at least a third position output, and preferably four simultaneously detected position outputs, with the motion control system including a position output processor for processing the multiply position outputs, which preferably compares the multiply outputs to determine if there is a suspected error output and exclude such suspected error output from the determination in a control system control loop step.

In an embodiment the invention includes a method of controlling motion. The method preferably includes providing a magnetic field generator for generating a magnetic field with a controllable field strength. The method preferably includes providing a field responsive controllable material, the field responsive controllable material affected by the magnetic field generator magnetic field. The method preferably includes providing a magnetic target. The method preferably includes providing at least a first electronic noncontacting magnetic sensor, the at least first electronic noncontacting magnetic sensor integrated on an operation electronic control board having a control board plane, the operation electronic control board in electrical communication with the magnetic field generator and the control board plane oriented relative to the magnetic target, wherein the at least a first electronic noncontacting magnetic sensor provides a detected measured position of the magnetic target with the controllable field strength generated in relationship to the detected measured position sensed by the at least first electronic noncontacting magnetic sensor.

Preferably the method of controlling motion includes providing a magnetic field generator 510 for generating a magnetic field 536 with a controllable field strength. The method preferably includes providing a field responsive controllable material 532, the field responsive controllable material affected by the magnetic field generator magnetic field. The method preferably includes providing a magnetic target 518. The method preferably includes providing at least a first electronic noncontacting magnetic sensor 524, the at least first electronic noncontacting magnetic sensor 524 integrated on an operation electronic control board 520 having a control board plane 522, the operation electronic control board 520 in electrical communication with the magnetic field generator 510 and the control board plane 522 oriented relative to the magnetic target 518, wherein the at least a first electronic noncontacting magnetic sensor 524 provides a detected measured position of the magnetic target 518 with the controllable field strength 536 generated in relationship to the detected measured position sensed by the at least first electronic noncontacting magnetic sensor 524. Preferably providing a field responsive controllable material 532 includes providing a material rheology which is field responsive, with the field responsive controllable material rheology affected and controllable by the magnetic field generator magnetic field 536, preferably the provided field responsive controllable material 532 is comprised of magnetic metal ferrous particles and lubricant, preferably dry ferrous particles and dry lubricant (preferably dry molybdenum disulfide). Preferably the provided magnetic target is a rotating magnetic target, that preferably provides a rotating magnetic field with the permanent magnet pole axis 534. Preferably the at least first electronic noncontacting magnetic sensors provide a detected measured rotational position of the magnetic target with the controllable magnetic field strength generated in relationship to the detected measured rotational position sensed by the at least first electronic noncontacting magnetic sensor. Preferably the at least first electronic noncontacting magnetic sensor 524 has a sensor plane 526 oriented with the control board plane 522. Preferably the at least first electronic noncontacting magnetic sensor plane 526 is oriented normal with the shaft axis of rotation 516. Preferably the sensor plane 526 is parallel with control board plane 522, with such normal to shaft axis of rotation 516, with the axis 516 intersecting sensor plane proximate the sensing center of the sensor 524. Preferably the method includes providing second electronic noncontacting magnetic sensor 528 with a sensor plane 530, with the second electronic noncontacting magnetic sensor 528 integrated on the operation electronic control board 520 with the second electronic noncontacting magnetic sensor plane 530 oriented parallel with the control board plane 522, with the control board plane 522 between the second electronic noncontacting magnetic sensor plane 530 and the first electronic noncontacting magnetic sensor plane 526. In an embodiment the electronic noncontacting magnetic sensors include magnetoresistive materials with electrical resistance changes in the presence of the magnetic target magnetic field, preferably with sensor magnetoresistive elements arranged in a Wheatstone bridge to sense the rotating magnetic field of the magnetic targets pole axis 534. In an embodiment the electronic noncontacting magnetic sensors include a Hall Effect element, preferably a plurality of oriented Hall Effect elements, preferably silicon semiconductor Hall effect elements integrated together to sense the rotating magnetic field of the magnetic targets pole axis 534.

Preferably the circuit board 520 includes electrical environmental protection circuitry. Preferably the circuit board circuitry includes electrical environmental protection circuitry 560 such as shown in FIG. 9. Preferably the circuit board circuitry includes a voltage regulator which drops down a first supplied voltage to the board down to a lowered sensor voltage for the sensor, such as the LM2931 voltage regulator such as shown in FIG. 9 dropping down the 12 volt power down to the 5 volt power supplied to the sensors 524, 528. Preferably the electrical environmental protection circuitry includes an electromagnetic filter providing EMC filtering protection. Preferably the circuit board 520 includes a first and a second power source, with the circuit board controlling the supply, conditioning and distribution of electrical power from the at least two power sources, to provide a controlled current 538 to the brake coil 546. The circuit board 520 provides control, supply, conditioning and distribution of current to the sensors 524, 528 and the EM coil 546 of the field generator 510, and output sensed angular position data such as shown in FIG. 10. Additionally in an embodiment the control system includes an outer control loop with the EM coil controlled outside the inner loop utilizing the output sensed angular position data from the sensors and board control system, such as with the FIG. 10 output data used to determine and produce a control current to EM coil 546 to control a relative motion with the brake 500. Preferably the at least two power sources provide for power supply to the same sensor. In a preferred embodiment the first power supply provides power to both sensors, with a backup secondary power supplied to the sensors from the second power supply. In preferred embodiments the 12 volt power to the circuit board 520 and the outputted sensed angular position data from the sensors are provided through the electronics outer loop conduit utilizing two separate cables routing the wiring into the second chamber 506. Preferably two separate cabled power supplies are supplied to the double sided board 520, with the circuit board 520 providing two isolated power supplies to a sensor. Preferably two separate cabled power supplies are supplied to the double sided board 520, with the circuit board 520 including electronics to send power to the EM brake coil 546, preferably at least with a control current 538 provided such as with the current control flyback diode steer current from two isolated power supplies supplied to the brake EM coil 546. In a preferred embodiment the board includes a processor that determines on board with an inner loop in the brake 500 to provide the control current 538 to the EM coil 546 based on the sensed position of the magnetic target 518, preferably with a position output processor processing the multiply position outputs from the sensors, which preferably compares the multiply outputs to determine if there is a suspected error output and exclude such suspected error output from the determination in the system control loop step. Preferably one set of electrical contact connections 548 deliver the control current 538 to the EM coil from the diode steering array. As shown in FIG. 10, the integrated oriented first and second sensors provide four detected target positions, preferably providing the absolute angular position of the rotating magnetic target 518, the shaft 512, and the rotor 508, preferably with the four outputs monitored and compared to detect a suspected erroneous output which in turn is ignored and not utilized in the determination of controlling the motion of the rotor with the field generator 510. FIG. 10 shows the positional outputs from two integrated circuit semiconductor sensor chip electronic noncontacting magnetic sensors 524, 528 mounted to opposing sides of a circuit board 520 for detecting the rotation of the target 518, the shaft 512, and the rotor 508. Channels 1 and 2 (Ch1, Ch2) show the at least two positional outputs (Ch1, Ch2) for the first integrated circuit semiconductor sensor chip electronic noncontacting magnetic sensor. Channels 3 and 4 (Ch3, Ch4) show the at least two positional outputs (Ch3, Ch4) for the second integrated circuit semiconductor sensor chip electronic noncontacting magnetic sensor. In this embodiment each of the integrated circuit semiconductor sensor chip electronic noncontacting magnetic sensors provided simultaneously two positional outputs (Ch1, Ch2) and (Ch3, Ch4). Preferably the electronic noncontacting magnetic sensor integrated circuit semiconductor sensor chip has at least two dies. Preferably the at least two dies are ASICs (Application Specific Integrated Circuits). In a preferred embodiment the at least two dies are side by side dies in the integrated circuit semiconductor sensor chip. In a preferred embodiment the at least two dies are vertically stacked dies in the integrated circuit semiconductor sensor chip. In a preferred embodiment the integrated circuit semiconductor sensor chip ASIC die include a magnetoresistive material, preferably with electrical resistance changes relative to the rotating shaft magnetic target magnetic field, preferably with magnetoresistive elements arranged in a Wheatstone bridge. In a preferred embodiment the integrated circuit semiconductor sensor chip ASIC die include a Hall Effect element, preferably a plurality of oriented Hall Effect elements, preferably silicon semiconductor Hall effect elements which detect changes relative to the rotating magnetic target magnetic field of the rotating shaft magnetic target.

It will be apparent to those skilled in the art that various modifications and variations can be made to the invention without departing from the spirit and scope of the invention. Thus, it is intended that the invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. It is intended that the scope of differing terms or phrases in the claims may be fulfilled by the same or different structure(s) or step(s). 

1. A controllable brake comprising: a housing comprising a first chamber and a second chamber, a shaft, the shaft extending through the first chamber and the second chamber with an axis of rotation, said shaft having a first shaft end, a controllable brake rotor made integral with the shaft, said rotor housed in the first chamber, a controllable brake magnetic field generator located in the first chamber proximate the controllable brake rotor, said controllable brake magnetic field generator for generating a controllable magnetic field strength, and, a controllable brake rotating magnetic target integral with said shaft proximate said first shaft end, said controllable brake rotating magnetic target housed in the second chamber, and a controllable brake electronics circuit board mounted in said second chamber, said controllable brake electronics circuit board having a control board plane, said control board plane oriented normal to said axis of rotation, a first electronic noncontacting magnetic sensor having a first sensor plane, said first electronic noncontacting magnetic sensor integrated on said controllable brake electronics circuit board with said first sensor plane parallel with said control board plane, a second electronic noncontacting magnetic sensor having a second sensor plane, said second electronic noncontacting magnetic sensor integrated on said controllable brake electronics circuit board with said second sensor plane parallel with said control board plane with said control board plane between said first sensor plane and said second sensor plane, said first electronic noncontacting magnetic sensor and said second electronic noncontacting magnetic sensor monitoring the rotation of said controllable brake rotating magnetic target and outputting a rotational position of said controllable brake rotating magnetic target wherein the controllable magnetic field strength generated by said controllable brake magnetic field generator is determined by said rotational position to control a relative motion of said controllable brake rotor.
 2. The controllable brake of claim 1, wherein said controllable brake rotating magnetic target is comprised of a permanent magnet with a north pole and a south pole opposed along a north south axis, said north south axis perpendicular with said shaft axis of rotation.
 3. The controllable brake of claim 1, said controllable brake including a field responsive controllable material in said first chamber, said field responsive controllable material being affected by said controllable magnetic field strength, and said magnetic field generator is adapted to generate a magnetic flux in a direction through said field responsive controllable material towards said rotor.
 4. The controllable brake of claim 1, said controllable brake including a field responsive controllable material sealed in said first chamber with a rheology of said field responsive controllable material being affected by said controllable magnetic field strength, and said magnetic field generator is adapted to generate a magnetic flux in a direction through said field responsive controllable material towards said rotor, and said controllable brake electronics circuit board provides a controlled current to said magnetic field generator.
 5. The controllable brake of claim 1 wherein said magnetic field generator comprises an electromagnetic coil and said controllable brake electronics circuit board is electrically connected with said magnetic field generator electromagnetic coil.
 6. The controllable brake of claim 1 wherein said electronic noncontacting magnetic sensor includes a magnetoresistive material.
 7. The controllable brake of claim 1 wherein said electronic noncontacting magnetic sensor includes a Hall Effect element.
 8. A controllable brakes, comprising: a rotating magnetic target, a magnetically permeable rotor, a shaft connected to said magnetically permeable rotor, a housing having a first housing chamber rotatably housing the magnetically permeable rotor therein, and including a magnetic field generator spaced from the magnetically permeable rotor, and configured and positioned for generating a controllable magnetic field to control a relative motion of said magnetically permeable rotor, and a second housing chamber containing control electronics therein, said second housing chamber electronics including at least a first oriented electronic noncontacting magnetic sensor, said at least first oriented electronic noncontacting magnetic sensor oriented relative to said rotating magnetic target and said shaft wherein said at least first oriented electronic noncontacting magnetic sensor monitors the rotation of said rotating magnetic target.
 9. The controllable brake of claim 8, wherein said at least first electronic noncontacting magnetic sensor provides at least two detected measured rotor positional outputs, and said at least two outputs used in a computational determination for applying a controlled magnetic field strength.
 10. The controllable brake of claim 9, wherein said at least first oriented electronic noncontacting magnetic sensor is integrated into a brake operation electronics control board mounted in said second sealed chamber wherein said brake operation electronics control board controls the operation of said controllable brake.
 11. The controllable brake of claim 9, including a second oriented electronic noncontacting magnetic sensor, wherein said first electronic noncontacting magnetic sensor and said second electronic noncontacting magnetic sensor are integrated into a brake operation electronics control board mounted in said second sealed chamber wherein said brake operation electronics control board controls and/or monitors the operation of said controllable brake.
 12. The controllable brake of claim 11, wherein said brake operation electronics control board has a less than one millimeter thickness between said first oriented electronic noncontacting magnetic sensor and said second oriented electronic noncontacting magnetic sensor, and said rotating magnetic target is comprised of a shaft oriented permanent magnet.
 13. A method of controlling motion, said method including: providing a housing having a first housing chamber and a second housing chamber, providing a shaft with a magnetically permeable rotor, said shaft including a rotating magnetic target distal from said magnetically permeable rotor, providing a magnetic field generator for generating a magnetic field with a controllable field strength for controlling a relative motion of said magnetically permeable rotor, providing at least a first electronic noncontacting magnetic sensor, said at least first electronic noncontacting magnetic sensor integrated on an operation electronic control board having a control board plane, disposing said magnetically permeable rotor, said magnetic field generator, in said first housing chamber, disposing said rotating magnetic target and said at least a first electronic noncontacting magnetic sensor in said second housing chamber, wherein said operation electronic control board is in electrical communication with said magnetic field generator and said control board plane is oriented relative to said rotating magnetic target, wherein said at least first electronic noncontacting magnetic sensor provides a detected measured rotational position of said rotating magnetic target with said controllable field strength generated in relationship to the detected measured rotational position sensed by said at least first electronic noncontacting magnetic sensor.
 14. A method as claimed in claim 13, said at least first electronic noncontacting magnetic sensor having a sensor plane oriented with said control board plane.
 15. A method as claimed in claim 14, said method including providing a second electronic noncontacting magnetic sensor with a sensor plane, said second electronic noncontacting magnetic sensor integrated on said operation electronic control board with said second electronic noncontacting magnetic sensor sensor plane oriented parallel with said control board plane, with said control board plane between said second electronic noncontacting magnetic sensor sensor plane and said first electronic noncontacting magnetic sensor sensor plane.
 16. A method as claimed in claim 13, wherein said at least first electronic noncontacting magnetic sensor includes a magnetoresistive material.
 17. A method as claimed in claim 13, wherein said at least first electronic noncontacting magnetic sensor includes a Hall Effect element.
 18. A method of making a motion control brake for controlling motion, said method including, providing a magnetic field generator for generating a magnetic field with a controllable field strength for controlling a relative motion of a movable brake member, providing a magnetic target which moves with said relative motion of said movable brake member, providing an electronic circuit board having a circuit board plane, a first electronic noncontacting magnetic sensor having a first sensor plane, said first electronic noncontacting magnetic sensor integrated on said electronic circuit board with said first sensor plane parallel with said circuit board plane, a second electronic noncontacting magnetic sensor having a second sensor plane, said second electronic noncontacting magnetic sensor integrated on said electronic circuit board with said second sensor plane parallel with said circuit board plane with said circuit board plane between said second sensor plane and said first sensor plane, disposing said electronic circuit board proximate said magnetic target wherein said first electronic noncontacting magnetic sensor and said second electronic noncontacting magnetic sensor provide a detected measured magnetic target position with the controllable field strength generated by said magnetic field generator determined by the detected measured magnetic target position.
 19. A method as claimed in claim 18, including providing a shaft wherein said movable brake member is comprised of a rotor and said magnetic target is comprised of a permanent magnet with a north pole and a south pole opposed along a north south axis with said movable brake member rotor made integral with said shaft and said magnetic target permanent magnet made integral with said shaft.
 20. A method as claimed in claim 19, wherein said shaft, said movable brake member rotor, and said magnetic target permanent magnet have an axis of rotation with said circuit board plane oriented normal to said axis of rotation.
 21. A method as claimed in claim 18 wherein said electronic circuit board has a less than one millimeter thickness between said first electronic noncontacting magnetic sensor and said second electronic noncontacting magnetic sensor.
 22. A method as claimed in claim 18 wherein said first electronic noncontacting magnetic sensor and said second electronic noncontacting magnetic sensor provide at least a first position output, at least a second position output, and at least a third position output.
 23. A method as claimed in claim 18, wherein said electronic noncontacting magnetic sensor includes a magnetoresistive material.
 24. A method as claimed in claim 18, wherein said electronic noncontacting magnetic sensor includes a Hall Effect element
 25. A method of making a control system, said method including, providing a control system rotating magnetic target having an axis of rotation, providing an control system electronic circuit board having a circuit board plane and a first circuit board side and an opposite second circuit board side, a first oriented electronic noncontacting magnetic sensor integrated on said electronic circuit board first circuit board side, a second oriented electronic noncontacting magnetic sensor integrated on said electronic circuit board second circuit board side, disposing said control system electronic circuit board proximate said control system rotating magnetic target with a projected extension of said axis of rotation extending through said first oriented electronic noncontacting magnetic sensor and said second oriented electronic noncontacting magnetic sensor wherein said first electronic noncontacting magnetic sensor and said second electronic noncontacting magnetic sensor provide a plurality of detected measured magnetic target rotary position outputs.
 26. A method as claimed in claim 25, wherein said magnetic target is comprised of a permanent magnet with a north pole and a south pole opposed along a north south axis with said north south axis perpendicular with said axis of rotation.
 27. A method as claimed in claim 25, wherein said electronic noncontacting magnetic sensor includes a magnetoresistive material
 28. A method as claimed in claim 25, wherein said electronic noncontacting magnetic sensor includes a Hall Effect element
 29. A method as claimed in claim 25 wherein said electronic circuit board has a less than one millimeter thickness between said first electronic noncontacting magnetic sensor and said second electronic noncontacting magnetic sensor.
 30. A method as claimed in claim 25 wherein said first electronic noncontacting magnetic sensor and said second electronic noncontacting magnetic sensor provide at least a first position output, at least a second position output, and at least a third position output.
 31. A method of controlling motion, said method including: providing a magnetic field generator for generating a magnetic field with a controllable field strength, providing a field responsive controllable material, said field responsive controllable material affected by said magnetic field generator magnetic field, providing a magnetic target, providing at least a first electronic noncontacting magnetic sensor, said at least first electronic noncontacting magnetic sensor integrated on an operation electronic control board having a control board plane, said operation electronic control board in electrical communication with said magnetic field generator and said control board plane oriented relative to said magnetic target, wherein said at least first electronic noncontacting magnetic sensor provides at least two detected measured positional outputs of said magnetic target with said controllable field strength generated in relationship to the at least two detected measured positional outputs.
 32. A method as claimed in claim 31, said at least first electronic noncontacting magnetic sensor has a sensor plane oriented with said control board plane.
 33. A method as claimed in claim 32, said method including providing a second electronic noncontacting magnetic sensor with a sensor plane, said second electronic noncontacting magnetic sensor integrated on said operation electronic control board with said second electronic noncontacting magnetic sensor sensor plane oriented parallel with said control board plane, with said control board plane between said second electronic noncontacting magnetic sensor sensor plane and said first electronic noncontacting magnetic sensor sensor plane.
 34. A method as claimed in claim 31, wherein said at least first electronic noncontacting magnetic sensor includes a magnetoresistive material.
 35. A method as claimed in claim 31, wherein said at least first electronic noncontacting magnetic sensor includes a Hall Effect element
 36. A controllable brake comprising: a housing comprising a first chamber and a second chamber, a shaft, the shaft extending through the first chamber and the second chamber with an axis of rotation, said shaft having a first shaft end, a controllable brake rotor made integral with the shaft, said rotor housed in the first chamber, said rotor having a rotation plane, a controllable brake magnetic field generator located in the first chamber proximate the controllable brake rotor, said controllable brake magnetic field generator for generating a controllable magnetic field strength, and a controllable brake rotating magnetic target integral with said shaft proximate said first shaft end, said controllable brake rotating magnetic target housed in the second chamber, and a controllable brake electronics first electronic noncontacting magnetic sensor having a first sensor plane, said first electronic noncontacting magnetic sensor mounted in said second chamber with said first sensor plane parallel with said controllable brake rotor rotation plane, said first electronic noncontacting magnetic sensor monitoring the rotation of said controllable brake rotating magnetic target and said controllable brake rotor and simultaneously outputting at least two rotational positions of said controllable brake rotor wherein the controllable magnetic field strength generated by said controllable brake magnetic field generator is determined by said rotational positions to control a relative motion of said controllable brake rotor. 